Section 3.2b
In the last section, we did plenty of analysis of logistic functions that were given to us… Now, we begin work on finding our very own logistic functions!!!
Find the logistic function that has an initial value of 5, a limit to growth of 45, and passing through (1, 9). First, recall the general equation: Limit to growth = c Initial Value = 5 Point (0, 5)
Find the logistic function that has an initial value of 5, a limit to growth of 45, and passing through (1, 9). Use the point (1, 9) to solve for b: Final Answer:
Find the logistic function that has an initial value of 19, a limit to growth of 76, and passing through (2, 49). General Equation: Limit to growth = c Initial Value = 19 Point (0, 19)
Find the logistic function that has an initial value of 19, a limit to growth of 76, and passing through (2, 49). Use the point (2, 49) to solve for b: Final Answer:
Determine a formula for the logistic function whose graph is shown below. (0, 6) (–2, 4) y = 33 Final Answer:
Use the data below to find an exponential regression for the population of the U.S., and use this regression to predict the U.S. population for the year Year U.S. Population (in millions Exponential Regression: Let t = years after 1900 How good is the fit of this model? What about the year 2000?: (About a 3% overestimate of the actual population)
Use the data below to find logistic regressions for the populations of FL and PA. Predict the m mm maximum sustainable populations for these two states. Graph and interpret the regressions. Year Populations of Two U.S. States (in millions) FloridaPennsylvania Let t = years after 1800
Use the data below to find logistic regressions for the populations maximum sustainable populations of FL and PA. Predict the maximum sustainable populations for these two states. Graph and interpret the regressions. Population of Florida: Population of Pennsylvania: Let’s graph them in the window [–10, 300] by [–5, 30]…
The half-life of a certain radioactive substance is 65 days. There are 3.5 grams present initially. When will there be less than 1 g remaining? The Model: There will be less than 1 gram remaining after approximately days where t is time in days Solve the equation:
The population of deer after t years in Cedar State Park is modeled by the function (a) What was the initial population of deer? (b) When will the number of deer be 600? Solve graphically: (c) What is the maximum number of deer possible in the park?
Find the logistic function modeling the population that has an initial population of 25,000, a limit to growth of 500,000, and a population of 32,000 after 4 years. General Equation: Limit to growth = c Initial Value = 25,000 Point (0, 25000)
Find the logistic function modeling the population that has an initial population of 25,000, a limit to growth of 500,000, and a population of 32,000 after 4 years. Plug in (4, 32000): Final Answer:
Find the logistic function modeling the population that has an initial population of 8, a limit to growth of 80, and a population of 60 after 7 years. General Equation: Limit to growth = c Initial Value = 8 Point (0, 8)
Find the logistic function modeling the population that has an initial population of 8, a limit to growth of 80, and a population of 60 after 7 years. Plug in (7, 60): Final Answer:
The 2000 population of Las Vegas, Nevada was 478,000 and is increasing at the rate of 6.28% each year. At that rate, when will the population be 1 million? The Model: In the year 2012, the population will be 1 million. Solve the equation: where t is years after 2000
Watauga High School has 1200 students. Bob, Carol, Ted, and Alice start a rumor, which spreads logistically according to the model below. The model predicts the number of students who have heard the rumor by the end of t days, where t = 0 is the day the rumor begins to spread. 1.How many students have heard the rumor by the end of Day 0? 30 students have heard the rumor on the day the rumor begins to spread.
Watauga High School has 1200 students. Bob, Carol, Ted, and Alice start a rumor, which spreads logistically according to the model below. The model predicts the number of students who have heard the rumor by the end of t days, where t = 0 is the day the rumor begins to spread. 2. How long does it take for 1000 students to hear the rumor? Toward the end of Day 6, the rumor has reached the ears of 1000 students Need to solve the equation: Solve graphically!!!